Healing of sub-critical femoral osteotomies in mice is unaffected by tacrolimus and deletion of recombination activating gene 1.

Clinical management of delayed healing or non-union of long bone fractures and segmental defects poses a substantial orthopaedic challenge. There are suggestions in the literature that bone healing may be enhanced by inhibiting the activities of T and B lymphocytes, but this remains controversial. To examine this matter in more detail, sub-critical-sized segmental defects were created in the femora of mice and it was assessed whether there might be a benefit from the administration of a Food and Drug Administration (FDA)-approved drug that blocks T cell activation (tacrolimus). Defects were stabilised using an internal plate. In certain groups of animals, 1 mg/kg or 10 mg/kg tacrolimus was delivered locally to the defect site for 3 or 7 d using an implanted osmotic pump with a silicon catheter directing drug delivery into the defect area. Healing was monitored by weekly X-ray and assessed at 12 weeks by mechanical testing, µCT and histology. Radiographic and histological evaluations revealed that 100 % of defects healed well regardless of tacrolimus dosage or duration. A comparison of healed C57BL/6 and Rag1-/- femora by µCT and ex vivo torsion testing showed no differences within mouse strains in terms of bone volume, tissue volume, bone volume/tissue volume ratio, shear modulus, torsional rigidity or torsional stiffness. These data failed to support an important role for tacrolimus in modulating the natural healing of segmental defects under those experimental conditions.

Characterization by serial deletion competition ELISAs of HIV-1 V3 loop epitopes recognized by monoclonal antibodies.

Characterization of the sites recognized by antibody on the V3 loop of the envelope glycoprotein gp120 of HIV-1 was done by competition ELISAs on a series of four mouse mAbs, a human mAb and a human Fab. The solid-phase antigen consisted of biotin-YNKRK-RIHIGPGRAFYTTKN, a sequence from the center of the V3 loop of gp120MN, applied to streptavidin-coated wells. Competing antigens were two series of peptides with the HIV-1MN sequence each serially deleted at either the N or C terminus but kept constant at the other terminus. For each series, the amino acid at the deleting end needed to give a minimum KD was identified. The epitope was defined as the sequence including both of the identified amino acids as terminal amino acids. For the six antibodies reported, the epitope length ranged from seven to 14 amino acids. Use of a cyclic peptide as competing fluid-phase antigen suggested the influence of conformational constraints on presumed "linear" epitopes. The operationally-defined epitope was longer than the contact residues in one of two instances in which the X-ray crystallographic structure had been determined. The longer estimates of epitope length in the current study based on competition ELISAs with serial deletions suggest that non-contact residues are significant both in epitope definition and in functional applications including immunogen design.

Broadly neutralizing monoclonal antibodies to the V3 region of HIV-1 can be elicited by peptide immunization.

The third hypervariable region (V3) of the HIV-1 envelope gp120 protein contains the principal neutralizing domain. Most neutralizing antibodies directed toward this region are very type-specific. Conserved sequences do exist within this region, however, and may prove useful in developing vaccines and therapeutic monoclonal antibodies (MABs) capable of targeting diverse HIV-1 isolates. We have used synthetic peptides containing conserved V3 sequences as immunogens to produce a panel of neutralizing MABs. The characterization of these MABs is described here. In addition, a series of in vitro assays has been developed that may be useful in predicting the neutralization potential of individual antibodies.